# encryption.py - module for handling encrypted values # coding: utf-8 # # Copyright (C) 2014-2025 Arthur de Jong # # This library is free software; you can redistribute it and/or # modify it under the terms of the GNU Lesser General Public # License as published by the Free Software Foundation; either # version 2.1 of the License, or (at your option) any later version. # # This library is distributed in the hope that it will be useful, # but WITHOUT ANY WARRANTY; without even the implied warranty of # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU # Lesser General Public License for more details. # # You should have received a copy of the GNU Lesser General Public # License along with this library; if not, write to the Free Software # Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA # 02110-1301 USA """Module that handles encrypted PSKC values. This module defines an Encryption class that handles the encryption key, algorithms and decryption. The encryption key can be derived using the KeyDerivation class. """ from __future__ import annotations import os import re from collections.abc import Sequence from typing import TYPE_CHECKING, Type if TYPE_CHECKING: # pragma: no cover (only for mypy) from cryptography.hazmat.primitives.ciphers import BlockCipherAlgorithm from pskc import PSKC def algorithm_key_lengths(algorithm: str | None) -> Sequence[int]: """Return the possible key lengths for the configured algorithm.""" from pskc.exceptions import DecryptionError if algorithm is None: raise DecryptionError('No algorithm specified') elif algorithm.endswith('#aes128-cbc') or \ algorithm.endswith('#aes192-cbc') or \ algorithm.endswith('#aes256-cbc'): return [int(algorithm[-7:-4]) // 8] elif algorithm.endswith('#tripledes-cbc') or \ algorithm.endswith('#kw-tripledes'): return [16, 24] elif algorithm.endswith('#kw-aes128') or \ algorithm.endswith('#kw-aes192') or \ algorithm.endswith('#kw-aes256'): return [int(algorithm[-3:]) // 8] elif (algorithm.endswith('#camellia128-cbc') or algorithm.endswith('#camellia192-cbc') or algorithm.endswith('#camellia256-cbc')): return [int(algorithm[-7:-4]) // 8] elif (algorithm.endswith('#kw-camellia128') or algorithm.endswith('#kw-camellia192') or algorithm.endswith('#kw-camellia256')): return [int(algorithm[-3:]) // 8] else: raise DecryptionError('Unsupported algorithm: %r' % algorithm) def _decrypt_cbc( algorithm: Type[BlockCipherAlgorithm], key: bytes, ciphertext: bytes, iv: bytes | None = None, ) -> bytes: """Decrypt the ciphertext and return the plaintext value.""" from cryptography.hazmat.backends import default_backend from cryptography.hazmat.primitives import padding from cryptography.hazmat.primitives.ciphers import Cipher, modes from pskc.exceptions import DecryptionError if not iv: iv = ciphertext[:algorithm.block_size // 8] # type: ignore[operator] ciphertext = ciphertext[algorithm.block_size // 8:] # type: ignore[operator] cipher = Cipher( algorithm(key), modes.CBC(iv), backend=default_backend()) # type: ignore[call-arg] decryptor = cipher.decryptor() unpadder = padding.PKCS7(algorithm.block_size).unpadder() # type: ignore[arg-type] try: return unpadder.update( decryptor.update(ciphertext) + decryptor.finalize()) + unpadder.finalize() except ValueError: raise DecryptionError('Invalid padding') def decrypt(algorithm: str | None, key: bytes | None, ciphertext: bytes, iv: bytes | None = None) -> bytes: """Decrypt the ciphertext and return the plaintext value.""" from cryptography.hazmat.primitives.ciphers import algorithms from pskc.exceptions import DecryptionError if key is None: raise DecryptionError('No key available') if algorithm is None: raise DecryptionError('No algorithm specified') if len(key) not in algorithm_key_lengths(algorithm): raise DecryptionError('Invalid key length') if algorithm.endswith('#aes128-cbc') or \ algorithm.endswith('#aes192-cbc') or \ algorithm.endswith('#aes256-cbc'): return _decrypt_cbc(algorithms.AES, key, ciphertext, iv) elif algorithm.endswith('#tripledes-cbc'): return _decrypt_cbc(algorithms.TripleDES, key, ciphertext, iv) elif algorithm.endswith('#kw-aes128') or \ algorithm.endswith('#kw-aes192') or \ algorithm.endswith('#kw-aes256'): from pskc.crypto.aeskw import unwrap as easkw_unwrap return easkw_unwrap(ciphertext, key) elif algorithm.endswith('#kw-tripledes'): from pskc.crypto.tripledeskw import unwrap as tripledeskw_unwrap return tripledeskw_unwrap(ciphertext, key) elif (algorithm.endswith('#camellia128-cbc') or algorithm.endswith('#camellia192-cbc') or algorithm.endswith('#camellia256-cbc')): return _decrypt_cbc(algorithms.Camellia, key, ciphertext, iv) elif (algorithm.endswith('#kw-camellia128') or # pragma: no branch algorithm.endswith('#kw-camellia192') or algorithm.endswith('#kw-camellia256')): from pskc.crypto.aeskw import unwrap as easkw_unwrap return easkw_unwrap(ciphertext, key, algorithm=algorithms.Camellia) # no fallthrough because algorithm_key_lengths() fails with unknown algo assert False # pragma: no cover (only for mypy) # noqa: B011 def _encrypt_cbc(algorithm: Type[BlockCipherAlgorithm], key: bytes, plaintext: bytes, iv: bytes | None = None) -> bytes: """Encrypt the provided value with the key using the algorithm.""" from cryptography.hazmat.backends import default_backend from cryptography.hazmat.primitives import padding from cryptography.hazmat.primitives.ciphers import Cipher, modes iv = iv or os.urandom(algorithm.block_size // 8) # type: ignore[operator] cipher = Cipher( algorithm(key), modes.CBC(iv), backend=default_backend()) # type: ignore[call-arg] encryptor = cipher.encryptor() padder = padding.PKCS7(algorithm.block_size).padder() # type: ignore[arg-type] return ( iv + encryptor.update( padder.update(plaintext) + padder.finalize()) + encryptor.finalize()) def encrypt(algorithm: str | None, key: bytes | None, plaintext: bytes, iv: bytes | None = None) -> bytes: """Encrypt the provided value with the key using the algorithm.""" from cryptography.hazmat.primitives.ciphers import algorithms from pskc.exceptions import EncryptionError if key is None: raise EncryptionError('No key available') if algorithm is None: raise EncryptionError('No algorithm specified') if len(key) not in algorithm_key_lengths(algorithm): raise EncryptionError('Invalid key length') if algorithm.endswith('#aes128-cbc') or \ algorithm.endswith('#aes192-cbc') or \ algorithm.endswith('#aes256-cbc'): return _encrypt_cbc(algorithms.AES, key, plaintext, iv) elif algorithm.endswith('#tripledes-cbc'): return _encrypt_cbc(algorithms.TripleDES, key, plaintext, iv) elif algorithm.endswith('#kw-aes128') or \ algorithm.endswith('#kw-aes192') or \ algorithm.endswith('#kw-aes256'): from pskc.crypto.aeskw import wrap as aeskw_wrap return aeskw_wrap(plaintext, key) elif algorithm.endswith('#kw-tripledes'): from pskc.crypto.tripledeskw import wrap as tripledeskw_wrap return tripledeskw_wrap(plaintext, key) elif (algorithm.endswith('#camellia128-cbc') or algorithm.endswith('#camellia192-cbc') or algorithm.endswith('#camellia256-cbc')): return _encrypt_cbc(algorithms.Camellia, key, plaintext, iv) elif (algorithm.endswith('#kw-camellia128') or # pragma: no branch algorithm.endswith('#kw-camellia192') or algorithm.endswith('#kw-camellia256')): from pskc.crypto.aeskw import wrap as aeskw_wrap return aeskw_wrap(plaintext, key, algorithm=algorithms.Camellia) # no fallthrough because algorithm_key_lengths() fails with unknown algo assert False # pragma: no cover (only for mypy) # noqa: B011 class KeyDerivation: """Handle key derivation. The algorithm property contains the key derivation algorithm to use. For PBDKF2 the following parameters are set: pbkdf2_salt: salt value pbkdf2_iterations: number of iterations to use pbkdf2_key_length: required key length in bytes pbkdf2_prf: name of pseudorandom function used """ def __init__(self) -> None: self._algorithm: str | None = None # PBKDF2 properties self.pbkdf2_salt: bytes | None = None self.pbkdf2_iterations: int | None = None self.pbkdf2_key_length: int | None = None self._pbkdf2_prf: str | None = None @property def algorithm(self) -> str | None: """Provide the key derivation algorithm used.""" if self._algorithm: return self._algorithm return None @algorithm.setter def algorithm(self, value: str | None) -> None: from pskc.algorithms import normalise_algorithm self._algorithm = normalise_algorithm(value) @property def pbkdf2_prf(self) -> str | None: """Provide the PBKDF2 pseudorandom function used.""" if self._pbkdf2_prf: return self._pbkdf2_prf return None @pbkdf2_prf.setter def pbkdf2_prf(self, value: str | None) -> None: from pskc.algorithms import normalise_algorithm self._pbkdf2_prf = normalise_algorithm(value) def derive_pbkdf2(self, password: str | bytes | bytearray) -> bytes: """Derive an encryption key from the provided password.""" from hashlib import pbkdf2_hmac from pskc.exceptions import KeyDerivationError prf = 'sha1' if self.pbkdf2_prf: match = re.search( r'^(.*#)?hmac-(?P[a-z0-9-]+)$', self.pbkdf2_prf) if match: prf = match.group('hash') else: raise KeyDerivationError( 'Unsupported PRF: %r' % self.pbkdf2_prf) if not all((password, self.pbkdf2_salt, self.pbkdf2_key_length, self.pbkdf2_iterations)): raise KeyDerivationError('Incomplete PBKDF2 configuration') # force conversion to bytestring if not isinstance(password, type(b'')): password = password.encode() # type: ignore[union-attr] try: return pbkdf2_hmac( prf, password, self.pbkdf2_salt, self.pbkdf2_iterations, # type: ignore[arg-type] self.pbkdf2_key_length) except ValueError: raise KeyDerivationError( 'Pseudorandom function unsupported: %r' % self.pbkdf2_prf) def derive(self, password: str | bytes | bytearray) -> bytes: """Derive a key from the password.""" from pskc.exceptions import KeyDerivationError if self.algorithm is None: raise KeyDerivationError('No algorithm specified') if self.algorithm.endswith('#pbkdf2'): return self.derive_pbkdf2(password) else: raise KeyDerivationError( 'Unsupported algorithm: %r' % self.algorithm) def setup_pbkdf2( self, password: str | bytes | bytearray, salt: bytes | None = None, salt_length: int = 16, key_length: int | None = None, iterations: int | None = None, prf: str | None = None, ) -> bytes: """Configure PBKDF2 key derivation properties.""" self.algorithm = 'pbkdf2' if salt is None: salt = os.urandom(salt_length) self.pbkdf2_salt = salt if iterations: self.pbkdf2_iterations = iterations elif self.pbkdf2_iterations is None: self.pbkdf2_iterations = 100000 if key_length: # pragma: no branch (always specified) self.pbkdf2_key_length = key_length if prf: self.pbkdf2_prf = prf return self.derive_pbkdf2(password) class Encryption: """Class for handling encryption keys that are used in the PSKC file. Encryption generally uses a symmetric key that is used to encrypt some of the information stored in PSKC files (typically the seed). This class provides the following values: id: identifier of the key algorithm: the encryption algorithm used key_names: list of names for the key key_name: (first) name of the key (usually there is only one) key: the key value itself (binary form) iv: optional initialization vector for CBC based encryption fields: a list of Key fields that will be encrypted on writing The key can either be assigned to the key property or derived using the `derive_key()` method. """ def __init__(self, pskc: PSKC) -> None: self.pskc = pskc self.id: str | None = None self._algorithm: str | None = None self.key_names: list[str] = [] self.key: bytes | None = None self.iv: bytes | None = None self.derivation = KeyDerivation() self.fields: list[str] = [] @property def key_name(self) -> str | None: """Provide the name of the (first) key.""" if self.key_names: return self.key_names[0] return None @key_name.setter def key_name(self, value: str | None) -> None: if value: self.key_names = [value] else: self.key_names = [] @property def algorithm(self) -> str | None: """Provide the encryption algorithm used.""" if self._algorithm: return self._algorithm return None @algorithm.setter def algorithm(self, value: str | None) -> None: from pskc.algorithms import normalise_algorithm self._algorithm = normalise_algorithm(value) @property def is_encrypted(self) -> bool: """Test whether the PSKC file requires a decryption key.""" from pskc.exceptions import DecryptionError try: for key in self.pskc.keys: key.secret, key.counter, key.time_offset key.time_interval, key.time_drift except DecryptionError: return True return False def derive_key(self, password: str | bytes | bytearray) -> None: """Derive a key from the password. The supplied password, together with the information embedded in the PSKC file (generally algorithm, salt, etc.) is used to create a decryption key. This function may raise a :exc:`~pskc.exceptions.KeyDerivationError` exception if key derivation fails. """ self.key = self.derivation.derive(password) def _setup_encryption( self, *, id: str | None = None, algorithm: str | None = None, key_name: str | None = None, key_names: list[str] | None = None, fields: list[str] | None = None, ) -> None: if id is not None: self.id = id if algorithm is not None: self.algorithm = algorithm if key_name is not None: self.key_name = key_name if key_names is not None: self.key_names = key_names if fields is not None: self.fields = fields # default encryption to AES128-CBC if not self.algorithm: self.algorithm = 'aes128-cbc' # default to encrypting the secret only if not self.fields: self.fields = ['secret'] # if we're using a CBC mode of encryption, add a MAC if self.algorithm.endswith('-cbc'): self.pskc.mac.setup() def setup_preshared_key( self, *, key: bytes | None = None, id: str | None = None, algorithm: str | None = None, key_length: int | None = None, key_name: str | None = None, key_names: list[str] | None = None, fields: list[str] | None = None, ) -> None: """Configure pre-shared key encryption when writing the file. :param key: the encryption key to use :param id: encryption key identifier :param algorithm: encryption algorithm :param key_length: encryption key length in bytes :param key_name: a name for the key :param key_names: a number of names for the key :param fields: a list of fields to encrypt This is a utility function to easily set up encryption. Encryption can also be set up by manually by setting the correct :class:`~pskc.encryption.Encryption` properties. This method will generate a key if required and set the passed values. By default AES128-CBC encryption will be configured and unless a key is specified one of the correct length will be generated. If the algorithm does not provide integrity checks (e.g. CBC-mode algorithms) integrity checking in the PSKC file will be set up using :func:`~pskc.mac.MAC.setup()`. By default only the :attr:`~pskc.key.Key.secret` property will be encrypted when writing the file. """ self._setup_encryption( id=id, algorithm=algorithm, key_name=key_name, key_names=key_names, fields=fields, ) if not key: key_length = key_length or self.algorithm_key_lengths[-1] key = os.urandom(key_length) self.key = key def setup_pbkdf2( self, password: str | bytes | bytearray, *, id: str | None = None, algorithm: str | None = None, key_name: str | None = None, key_names: list[str] | None = None, key_length: int | None = None, fields: list[str] | None = None, salt: bytes | None = None, salt_length: int = 16, iterations: int | None = None, prf: str | None = None, ) -> None: """Configure password-based PSKC encryption when writing the file. :param password: the password to use (required) :param id: encryption key identifier :param algorithm: encryption algorithm :param key_length: encryption key length in bytes :param key_name: a name for the key :param key_names: a number of names for the key :param fields: a list of fields to encrypt :param salt: PBKDF2 salt :param salt_length: used when generating random salt :param iterations: number of PBKDF2 iterations :param prf: PBKDF2 pseudorandom function Defaults for the above parameters are similar to those for :func:`setup_preshared_key()` but the password parameter is required. By default 12000 iterations will be used and a random salt with the length of the to-be-generated encryption key will be used. """ self._setup_encryption( id=id, algorithm=algorithm, key_name=key_name, key_names=key_names, fields=fields, ) self.key = self.derivation.setup_pbkdf2( password, salt=salt, salt_length=salt_length, key_length=key_length or self.algorithm_key_lengths[-1], iterations=iterations, prf=prf, ) @property def algorithm_key_lengths(self) -> Sequence[int]: """Provide the possible key lengths for the configured algorithm.""" return algorithm_key_lengths(self.algorithm) def decrypt_value(self, cipher_value: bytes, algorithm: str | None = None) -> bytes: """Decrypt the cipher_value and return the plaintext value.""" return decrypt( algorithm or self.algorithm, self.key, cipher_value, self.iv) def encrypt_value(self, plaintext: bytes) -> bytes: """Encrypt the provided value and return the cipher_value.""" cipher_value = encrypt(self.algorithm, self.key, plaintext, self.iv) if self.iv: cipher_value = cipher_value[len(self.iv):] return cipher_value def remove_encryption(self) -> None: """Decrypt all values and remove the encryption from the PSKC file. This can be used to read and encrypted PSKC file, decrypt the file, remove the encryption and output an unencrypted PSKC file or to replace the encryption algorithm. """ # decrypt all values and store decrypted values for key in self.pskc.keys: key.secret = key.secret key.counter = key.counter key.time_offset = key.time_offset key.time_interval = key.time_interval key.time_drift = key.time_drift # remove MAC configuration self.pskc.mac.algorithm = None self.pskc.mac.key = None # remove encryption configuration self.id = None self.algorithm = None self.key_names = [] self.key = None self.iv = None self.fields = [] # remove key derivation configuration self.derivation.algorithm = None self.derivation.pbkdf2_salt = None self.derivation.pbkdf2_iterations = None self.derivation.pbkdf2_key_length = None self.derivation.pbkdf2_prf = None